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Institut
- Fachbereich 7 (13) (entfernen)
In Europa ist die moderne Landwirtschaft eine der häufigsten Formen der Landnutzung, allerdings wird sie auch mit negativen Auswirkungen auf die Biodiversität in Agrarlandschaften in Verbindung gebracht. Lepidoptera (Nacht- und Tagfalter) bilden eine artenreiche Gruppe in Agrarsystemen, doch die Populationen vieler Falterarten sind rückläufig. Zu den Zielen der vorliegenden Arbeit gehörte es, Feldsäume in Agrarlandschaften zu erfassen und zu charakterisieren, Effekte realistischer Eintragsraten von Agrarchemikalien (Dünger und Pestizide) in Feldsäumen auf Lepidoptera zu untersuchen und Informationen zu den Bestäubungsleistungen von Nachtfaltern zu sammeln.
Feldsäume sind zwar häufige semi-natürliche Habitatelemente in Agrarökosystemen, aber es gibt nur wenige Informationen über ihre Struktur, Größe und Breite. Daher wurden Feldsäume in zwei deutschen Agrarlandschaften (je 4.000 ha) erfasst und es zeigte sich, dass ein Großteil dieser Säume schmaler als 3 m war (Rheinland-Pfalz: 85% der Feldsaumlänge, Brandenburg: 45% der Feldsaumlänge). In Deutschland müssen Landwirte bei solchen schmalen Feldsäumen keine Maßnahmen zur Verminderung von Pestizideinträgen (z.B. Pufferzonen) umsetzen. Agrarchemikalien werden deshalb insbesondere durch Überspritzung und Abdrift in schmale Feldsäume eingetragen. In solchen schmalen Feldsäumen konnten zwar Raupen nachgewiesen werden, doch ihre mittlere Abundanz war um 35 – 60% niedriger als auf Vergleichsflächen (Wiesen). Im Rahmen eines Feldversuchs sowie in Laborexperimenten zeigte sich, dass Raupen sensitiv auf Insektizideinträge (Pyrethroid, Lambda-Cyhalothrin) regieren. Zudem wurden auf insektizid-behandelten Silene latifolia Pflanzen 40% weniger Eier von Hadena bicruris Faltern gefunden als auf unbehandelten Kontrollpflanzen und die Blüten der behandelten Pflanzen wurden seltener von Nachtfaltern bestäubt. Lepidoptera können neben Insektizid- auch von Herbizideinträgen beeinflussen werden. Ranunculus acris L. Pflanzen wurden mit subletalen Raten eines Sulfonylurea-Herbizids behandelt und dann als Futterpflanzen für Mamestra brassicae L. Raupen genutzt; dies führte zu signifikant geringeren Raupengewichten, einer verlängerten Zeit bis zur Verpuppung und einer verlängerten Gesamtentwicklungsdauer verglichen mit Raupen, die an Kontrollpflanzen fraßen. Ursachen hierfür waren möglicherweise ein geringerer Nährwert oder eine höhere Konzentration von Abwehrstoffen in den herbizid-behandelten Pflanzen. Düngereinträge führten zu einer geringfügigen Erhöhung der Raupenabundanz in dem Feldversuch. Langfristig reduziert Dünger jedoch die Pflanzenvielfalt und dadurch wahrscheinlich auch die Raupendiversität.
Nachtfalter wie Noctuidae und Sphingidae sind Bestäuber für zahlreiche Pflanzenarten, z.B. viele Orchidaceae und Caryophyllaceae. Obwohl sie in den Agrarökosystemen der gemäßigten Breiten wahrscheinlich keine bedeutenden Bestäuber für Kulturpflanzen sind, können Nachtfalter aber für die Bestäubung der Wildpflanzen in semi-natürlichen Habitaten von Relevanz sein. Dabei wird die Rolle der Nachtfalter als Bestäuber zurzeit vermutlich unterschätzt und es werden Langzeitstudien benötigt, um die zeitlichen Schwankungen in ihrer Abundanz und Artenzusammensetzung berücksichtigen zu können.
Lepidopteren bilden eine artenreiche Organismengruppe in Agrarlandschaften, die auch wesentliche Ökosystem-Dienstleistungen erfüllen. Um Nacht- und Tagfalter besser zu schützen, sollten Einträge von Agrarchemikalien in (schmale) Feldsaumhabitate reduziert werden, beispielsweise durch Maßnahmen zur Risikominderung von Pestiziden und Agrarumweltprogramme.
The increasing, anthropogenic demand for chemicals has created large environmental problems with repercussions for the health of the environment, especially aquatic ecosystems. As a result, the awareness of the public and decision makers on the risks from chemical pollution has increased over the past half-century, prompting a large number of studies in the field of ecological toxicology (ecotoxicology). However, the majority of ecotoxicological studies are laboratory based, and the few studies extrapolating toxicological effects in the field are limited to local and regional levels. Chemical risk assessment on large spatial scales remains largely unexplored, and therefore, the potential large-scale effects of chemicals may be overlooked.
To answer ecotoxicological questions, multidisciplinary approaches that transcend classical chemical and toxicological concepts are required. For instance, the current models for toxicity predictions - which are mainly based on the prediction of toxicity for a single compound and species - can be expanded to simultaneously predict the toxicity for different species and compounds. This can be done by integrating chemical concepts such as the physicochemical properties of the compounds with evolutionary concepts such as the similarity of species. This thesis introduces new, multidisciplinary tools for chemical risk assessments, and presents for the first time a chemical risk assessment on the continental scale.
After a brief introduction of the main concepts and objectives of the studies, this thesis starts by presenting a new method for assessing the physiological sensitivity of macroinvertebrate species to heavy metals (Chapter 2). To compare the sensitivity of species to different heavy metals, toxicity data were standardized to account for the different laboratory conditions. These rankings were not significantly different for different heavy metals, allowing the aggregation of physiological sensitivity into a single ranking.
Furthermore, the toxicological data for macroinvertebrates were used as input data to develop and validate prediction models for heavy metal toxicity, which are currently lacking for a wide array of species (Chapter 3). Apart from the toxicity data, the phylogenetic information of species (evolutionary relationships among species) and the physicochemical parameters for heavy metals were used. The constructed models had a good explanatory power for the acute sensitivity of species to heavy metals with the majority of the explained variance attributed to phylogeny. Therefore, the integration of evolutionary concepts (relatedness and similarity of species) with the chemical parameters used in ecotoxicology improved prediction models for species lacking experimental toxicity data. The ultimate goal of the prediction models developed in this thesis is to provide accurate predictions of toxicity for a wide range of species and chemicals, which is a crucial prerequisite for conducting chemical risk assessment.
The latter was conducted for the first time on the continental scale (Chapter 4), by making use of a dataset of 4,000 sites distributed throughout 27 European countries and 91 respective river basins. Organic chemicals were likely to exert acute risks for one in seven sites analyzed, while chronic risk was prominent for almost half of the sites. The calculated risks are potentially underestimated by the limited number of chemicals that are routinely analyzed in monitoring programmes, and a series of other uncertainties related with the limit of quantification, the presence of mixtures, or the potential for sublethal effects not covered by direct toxicity.
Furthermore, chemical risk was related to agricultural and urban areas in the upstream catchments. The analysis of ecological data indicated chemical impacts on the ecological status of the river systems; however, it is difficult to discriminate the effects of chemical pollution from other stressors that river systems are exposed to. To test the hypothesis of multiple stressors, and investigate the relative importance of organic toxicants, a dataset for German streams is used in chapter 5. In that study, the risk from abiotic (habitat degradation, organic chemicals, and nutrients enrichment) and biotic stressors (invasive species) was investigated. The results indicated that more than one stressor influenced almost all sites. Stream size and ecoregions influenced the distribution of risks, e.g., the risks for habitat degradation, organic chemicals and invasive species increased with the stream size; whereas organic chemicals and nutrients were more likely to influence lowland streams. In order to successfully mitigate the effects of pollutants in river systems, co-occurrence of stressors has to be considered. Overall, to successfully apply integrated water management strategies, a framework involving multiple environmental stressors on large spatial scales is necessary. Furthermore, to properly address the current research needs in ecotoxicology, a multidisciplinary approach is necessary which integrates fields such as, toxicology, ecology, chemistry and evolutionary biology.
Aquatic macrophytes can contribute to the retention of organic contaminants in streams, whereas knowledge on the dynamics and the interaction of the determining processes is very limited. The objective of the present study was thus to assess how aquatic macrophytes influence the distribution and the fate of organic contaminants in small vegetated streams. In a first study that was performed in vegetated stream mesocosms, the peak reductions of five compounds were significantly higher in four vegetated stream mesocosms compared to a stream mesocosm without vegetation. Compound specific sorption to macrophytes was determined, the mass retention in the vegetated streams, however, did not explain the relationship between the mitigation of contaminant peaks and macrophyte coverage. A subsequent mesocosm study revealed that the mitigation of peak concentrations in the stream mesocosms was governed by two fundamentally different processes: dispersion and sorption. Again, the reductions of the peak concentrations of three different compounds were in the same order of magnitude in a sparsely and a densely vegetated stream mesocosm, respectively, but higher compared to an unvegetated stream mesocosm. The mitigation of the peak reduction in the sparsely vegetated stream mesocosm was found to be fostered by longitudinal dispersion as a result of the spatial distribution of the macrophytes in the aqueous phase. The peak reduction attributable to longitudinal dispersion was, however, reduced in the densely vegetated stream mesocosm, which was compensated by compound-specific but time-limited and reversible sorption to macrophytes. The observations on the reversibility of sorption processes were subsequently confirmed by laboratory experiments. The experiments revealed that sorption to macrophytes lead to compound specific elimination from the aqueous phase during the presence of transient contaminant peaks in streams. After all, these sorption processes were found to be fully reversible, which results in the release of the primarily adsorbed compounds, once the concentrations in the aqueous phase starts to decrease. Nevertheless, the results of the present thesis demonstrate that the processes governing the mitigation of contaminant loads in streams are fundamentally different to those already described for non-flowing systems. In addition, the present thesis provides knowledge on how the interaction of macrophyte-induced processes in streams contributes to mitigate loads of organic contaminants and the related risk for aquatic environments.